Your search keyword '"Slaughterbeck, Cliff"' showing total 5 results

1. A high-resolution transcriptomic and spatial atlas of cell types in the whole mouse brain

Author

Yao, Zizhen, van Velthoven, Cindy T. J., Kunst, Michael, Zhang, Meng, McMillen, Delissa, Lee, Changkyu, Jung, Won, Goldy, Jeff, Abdelhak, Aliya, Aitken, Matthew, Baker, Katherine, Baker, Pamela, Barkan, Eliza, Bertagnolli, Darren, Bhandiwad, Ashwin, Bielstein, Cameron, Bishwakarma, Prajal, Campos, Jazmin, Carey, Daniel, Casper, Tamara, Chakka, Anish Bhaswanth, Chakrabarty, Rushil, Chavan, Sakshi, Chen, Min, Clark, Michael, Close, Jennie, Crichton, Kirsten, Daniel, Scott, DiValentin, Peter, Dolbeare, Tim, Ellingwood, Lauren, Fiabane, Elysha, Fliss, Timothy, Gee, James, Gerstenberger, James, Glandon, Alexandra, Gloe, Jessica, Gould, Joshua, Gray, James, Guilford, Nathan, Guzman, Junitta, Hirschstein, Daniel, Ho, Windy, Hooper, Marcus, Huang, Mike, Hupp, Madie, Jin, Kelly, Kroll, Matthew, Lathia, Kanan, Leon, Arielle, Li, Su, Long, Brian, Madigan, Zach, Malloy, Jessica, Malone, Jocelin, Maltzer, Zoe, Martin, Naomi, McCue, Rachel, McGinty, Ryan, Mei, Nicholas, Melchor, Jose, Meyerdierks, Emma, Mollenkopf, Tyler, Moonsman, Skyler, Nguyen, Thuc Nghi, Otto, Sven, Pham, Trangthanh, Rimorin, Christine, Ruiz, Augustin, Sanchez, Raymond, Sawyer, Lane, Shapovalova, Nadiya, Shepard, Noah, Slaughterbeck, Cliff, Sulc, Josef, Tieu, Michael, Torkelson, Amy, Tung, Herman, Valera Cuevas, Nasmil, Vance, Shane, Wadhwani, Katherine, Ward, Katelyn, Levi, Boaz, Farrell, Colin, Young, Rob, Staats, Brian, Wang, Ming-Qiang Michael, Thompson, Carol L., Mufti, Shoaib, Pagan, Chelsea M., Kruse, Lauren, Dee, Nick, Sunkin, Susan M., Esposito, Luke, Hawrylycz, Michael J., Waters, Jack, Ng, Lydia, Smith, Kimberly, Tasic, Bosiljka, Zhuang, Xiaowei, and Zeng, Hongkui

Abstract

The mammalian brain consists of millions to billions of cells that are organized into many cell types with specific spatial distribution patterns and structural and functional properties1–3. Here we report a comprehensive and high-resolution transcriptomic and spatial cell-type atlas for the whole adult mouse brain. The cell-type atlas was created by combining a single-cell RNA-sequencing (scRNA-seq) dataset of around 7 million cells profiled (approximately 4.0 million cells passing quality control), and a spatial transcriptomic dataset of approximately 4.3 million cells using multiplexed error-robust fluorescence in situ hybridization (MERFISH). The atlas is hierarchically organized into 4 nested levels of classification: 34 classes, 338 subclasses, 1,201 supertypes and 5,322 clusters. We present an online platform, Allen Brain Cell Atlas, to visualize the mouse whole-brain cell-type atlas along with the single-cell RNA-sequencing and MERFISH datasets. We systematically analysed the neuronal and non-neuronal cell types across the brain and identified a high degree of correspondence between transcriptomic identity and spatial specificity for each cell type. The results reveal unique features of cell-type organization in different brain regions—in particular, a dichotomy between the dorsal and ventral parts of the brain. The dorsal part contains relatively fewer yet highly divergent neuronal types, whereas the ventral part contains more numerous neuronal types that are more closely related to each other. Our study also uncovered extraordinary diversity and heterogeneity in neurotransmitter and neuropeptide expression and co-expression patterns in different cell types. Finally, we found that transcription factors are major determinants of cell-type classification and identified a combinatorial transcription factor code that defines cell types across all parts of the brain. The whole mouse brain transcriptomic and spatial cell-type atlas establishes a benchmark reference atlas and a foundational resource for integrative investigations of cellular and circuit function, development and evolution of the mammalian brain.

Published

2023

2. Survey of spiking in the mouse visual system reveals functional hierarchy

Author

Siegle, Joshua H., Jia, Xiaoxuan, Durand, Séverine, Gale, Sam, Bennett, Corbett, Graddis, Nile, Heller, Greggory, Ramirez, Tamina K., Choi, Hannah, Luviano, Jennifer A., Groblewski, Peter A., Ahmed, Ruweida, Arkhipov, Anton, Bernard, Amy, Billeh, Yazan N., Brown, Dillan, Buice, Michael A., Cain, Nicolas, Caldejon, Shiella, Casal, Linzy, Cho, Andrew, Chvilicek, Maggie, Cox, Timothy C., Dai, Kael, Denman, Daniel J., de Vries, Saskia E. J., Dietzman, Roald, Esposito, Luke, Farrell, Colin, Feng, David, Galbraith, John, Garrett, Marina, Gelfand, Emily C., Hancock, Nicole, Harris, Julie A., Howard, Robert, Hu, Brian, Hytnen, Ross, Iyer, Ramakrishnan, Jessett, Erika, Johnson, Katelyn, Kato, India, Kiggins, Justin, Lambert, Sophie, Lecoq, Jerome, Ledochowitsch, Peter, Lee, Jung Hoon, Leon, Arielle, Li, Yang, Liang, Elizabeth, Long, Fuhui, Mace, Kyla, Melchior, Jose, Millman, Daniel, Mollenkopf, Tyler, Nayan, Chelsea, Ng, Lydia, Ngo, Kiet, Nguyen, Thuyahn, Nicovich, Philip R., North, Kat, Ocker, Gabriel Koch, Ollerenshaw, Doug, Oliver, Michael, Pachitariu, Marius, Perkins, Jed, Reding, Melissa, Reid, David, Robertson, Miranda, Ronellenfitch, Kara, Seid, Sam, Slaughterbeck, Cliff, Stoecklin, Michelle, Sullivan, David, Sutton, Ben, Swapp, Jackie, Thompson, Carol, Turner, Kristen, Wakeman, Wayne, Whitesell, Jennifer D., Williams, Derric, Williford, Ali, Young, Rob, Zeng, Hongkui, Naylor, Sarah, Phillips, John W., Reid, R. Clay, Mihalas, Stefan, Olsen, Shawn R., and Koch, Christof

Abstract

The anatomy of the mammalian visual system, from the retina to the neocortex, is organized hierarchically1. However, direct observation of cellular-level functional interactions across this hierarchy is lacking due to the challenge of simultaneously recording activity across numerous regions. Here we describe a large, open dataset—part of the Allen Brain Observatory2—that surveys spiking from tens of thousands of units in six cortical and two thalamic regions in the brains of mice responding to a battery of visual stimuli. Using cross-correlation analysis, we reveal that the organization of inter-area functional connectivity during visual stimulation mirrors the anatomical hierarchy from the Allen Mouse Brain Connectivity Atlas3. We find that four classical hierarchical measures—response latency, receptive-field size, phase-locking to drifting gratings and response decay timescale—are all correlated with the hierarchy. Moreover, recordings obtained during a visual task reveal that the correlation between neural activity and behavioural choice also increases along the hierarchy. Our study provides a foundation for understanding coding and signal propagation across hierarchically organized cortical and thalamic visual areas.

Published

2021

3. A large-scale standardized physiological survey reveals functional organization of the mouse visual cortex

Author

de Vries, Saskia E. J., Lecoq, Jerome A., Buice, Michael A., Groblewski, Peter A., Ocker, Gabriel K., Oliver, Michael, Feng, David, Cain, Nicholas, Ledochowitsch, Peter, Millman, Daniel, Roll, Kate, Garrett, Marina, Keenan, Tom, Kuan, Leonard, Mihalas, Stefan, Olsen, Shawn, Thompson, Carol, Wakeman, Wayne, Waters, Jack, Williams, Derric, Barber, Chris, Berbesque, Nathan, Blanchard, Brandon, Bowles, Nicholas, Caldejon, Shiella D., Casal, Linzy, Cho, Andrew, Cross, Sissy, Dang, Chinh, Dolbeare, Tim, Edwards, Melise, Galbraith, John, Gaudreault, Nathalie, Gilbert, Terri L., Griffin, Fiona, Hargrave, Perry, Howard, Robert, Huang, Lawrence, Jewell, Sean, Keller, Nika, Knoblich, Ulf, Larkin, Josh D., Larsen, Rachael, Lau, Chris, Lee, Eric, Lee, Felix, Leon, Arielle, Li, Lu, Long, Fuhui, Luviano, Jennifer, Mace, Kyla, Nguyen, Thuyanh, Perkins, Jed, Robertson, Miranda, Seid, Sam, Shea-Brown, Eric, Shi, Jianghong, Sjoquist, Nathan, Slaughterbeck, Cliff, Sullivan, David, Valenza, Ryan, White, Casey, Williford, Ali, Witten, Daniela M., Zhuang, Jun, Zeng, Hongkui, Farrell, Colin, Ng, Lydia, Bernard, Amy, Phillips, John W., Reid, R. Clay, and Koch, Christof

Abstract

To understand how the brain processes sensory information to guide behavior, we must know how stimulus representations are transformed throughout the visual cortex. Here we report an open, large-scale physiological survey of activity in the awake mouse visual cortex: the Allen Brain Observatory Visual Coding dataset. This publicly available dataset includes the cortical activity of nearly 60,000 neurons from six visual areas, four layers, and 12 transgenic mouse lines in a total of 243 adult mice, in response to a systematic set of visual stimuli. We classify neurons on the basis of joint reliabilities to multiple stimuli and validate this functional classification with models of visual responses. While most classes are characterized by responses to specific subsets of the stimuli, the largest class is not reliably responsive to any of the stimuli and becomes progressively larger in higher visual areas. These classes reveal a functional organization wherein putative dorsal areas show specialization for visual motion signals.

Published

2020

4. Aberration-free multi-plane imaging of neural activity from the mammalian brain using a fast-switching liquid crystal spatial light modulator

Author

Liu, Rui, Ball, Neil, Brockill, James, Kuan, Leonard, Millman, Daniel, White, Cassandra, Leon, Arielle, Williams, Derric, Nishiwaki, Shig, de Vries, Saskia, Larkin, Josh, Sullivan, David, Slaughterbeck, Cliff, Farrell, Colin, and Saggau, Peter

Abstract

We report a novel two-photon fluorescence microscope based on a fast-switching liquid crystal spatial light modulator and a pair of galvo-resonant scanners for large-scale recording of neural activity from the mammalian brain. The spatial light modulator is used to achieve fast switching between different imaging planes in multi-plane imaging and correct for intrinsic optical aberrations associated with this imaging scheme. The utilized imaging technique is capable of monitoring the neural activity from large populations of neurons with known coordinates spread across different layers of the neocortex in awake and behaving mice, regardless of the fluorescent labeling strategy. During each imaging session, all visual stimulus driven somatic activity could be recorded in the same behavior state. We observed heterogeneous response to different types of visual stimuli from ∼ 3,300 excitatory neurons reaching from layer II/III to V of the striate cortex.

Published

2019

5. Classification of electrophysiological and morphological neuron types in the mouse visual cortex

Author

Gouwens, Nathan, Sorensen, Staci, Berg, Jim, Lee, Changkyu, Jarsky, Tim, Ting, Jonathan, Sunkin, Susan, Feng, David, Anastassiou, Costas, Barkan, Eliza, Bickley, Kris, Blesie, Nicole, Braun, Thomas, Brouner, Krissy, Budzillo, Agata, Caldejon, Shiella, Casper, Tamara, Castelli, Dan, Chong, Peter, Crichton, Kirsten, Cuhaciyan, Christine, Daigle, Tanya, Dalley, Rachel, Dee, Nick, Desta, Tsega, Ding, Song-Lin, Dingman, Samuel, Doperalski, Alyse, Dotson, Nadezhda, Egdorf, Tom, Fisher, Michael, de Frates, Rebecca, Garren, Emma, Garwood, Marissa, Gary, Amanda, Gaudreault, Nathalie, Godfrey, Keith, Gorham, Melissa, Gu, Hong, Habel, Caroline, Hadley, Kristen, Harrington, James, Harris, Julie, Henry, Alex, Hill, DiJon, Josephsen, Sam, Kebede, Sara, Kim, Lisa, Kroll, Matthew, Lee, Brian, Lemon, Tracy, Link, Katherine, Liu, Xiaoxiao, Long, Brian, Mann, Rusty, McGraw, Medea, Mihalas, Stefan, Mukora, Alice, Murphy, Gabe, Ng, Lindsay, Ngo, Kiet, Nguyen, Thuc, Nicovich, Philip, Oldre, Aaron, Park, Daniel, Parry, Sheana, Perkins, Jed, Potekhina, Lydia, Reid, David, Robertson, Miranda, Sandman, David, Schroedter, Martin, Slaughterbeck, Cliff, Soler-Llavina, Gilberto, Sulc, Josef, Szafer, Aaron, Tasic, Bosiljka, Taskin, Naz, Teeter, Corinne, Thatra, Nivretta, Tung, Herman, Wakeman, Wayne, Williams, Grace, Young, Rob, Zhou, Zhi, Farrell, Colin, Peng, Hanchuan, Hawrylycz, Michael, Lein, Ed, Ng, Lydia, Arkhipov, Anton, Bernard, Amy, Phillips, John, Zeng, Hongkui, and Koch, Christof

Abstract

Understanding the diversity of cell types in the brain has been an enduring challenge and requires detailed characterization of individual neurons in multiple dimensions. To systematically profile morpho-electric properties of mammalian neurons, we established a single-cell characterization pipeline using standardized patch-clamp recordings in brain slices and biocytin-based neuronal reconstructions. We built a publicly accessible online database, the Allen Cell Types Database, to display these datasets. Intrinsic physiological properties were measured from 1,938 neurons from the adult laboratory mouse visual cortex, morphological properties were measured from 461 reconstructed neurons, and 452 neurons had both measurements available. Quantitative features were used to classify neurons into distinct types using unsupervised methods. We established a taxonomy of morphologically and electrophysiologically defined cell types for this region of the cortex, with 17 electrophysiological types, 38 morphological types and 46 morpho-electric types. There was good correspondence with previously defined transcriptomic cell types and subclasses using the same transgenic mouse lines. Gouwens et al. established a morpho-electrical taxonomy of cell types for the mouse visual cortex via unsupervised clustering analysis of multiple quantitative features from 1,938 neurons available online at the Allen Cell Types Database.

Published

2019